T cell-specific non-viral DNA delivery and in vivo CAR-T generation using targeted lipid nanoparticles.

IF 10.3 1区医学 Q1 IMMUNOLOGY

Journal for Immunotherapy of Cancer Pub Date : 2025-07-13 DOI:10.1136/jitc-2025-011759

Jaime Fernández Bimbo, Eline van Diest, Daniel E Murphy, Ator Ashoti, Martijn J W Evers, Suneel A Narayanavari, Diana Pereira Vaz, Hanneke Rijssemus, Christina Zotou, Nadine Saber, Zhiyong Lei, Peter Mayrhofer, Maurits Geerlings, Raymond Schiffelers, Jacek Lubelski

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引用次数: 0

Abstract

Background: Ex vivo chimeric antigen receptor (CAR)-T therapies have revolutionized cancer treatment. However, treatment accessibility is hindered by high costs, long manufacturing times, and the need for specialized centers and inpatient care. Strategies to generate CAR-T cells in vivo have emerged as a promising alternative that could bypass CAR-T manufacturing bottlenecks. Most current in vivo CAR-T approaches, while demonstrating encouraging preclinical efficacy, rely on transient messenger RNA (mRNA) delivery or viral vectors which both have limitations in terms of efficiency, durability, and scalability. To address these challenges, we developed a novel DNA-based targeted lipid nanoparticle (LNP) which we termed NCtx.

Methods: Minicircle DNA (mcDNA) encoding a CAR construct and SB100x transposase mRNA were encapsulated within a novel lipid formulation which was functionalized with T cell-specific anti-CD7 and anti-CD3 binders. In vitro, we evaluated T cell specificity, mcDNA and mRNA transfection efficiency, transposon-mediated CAR integration and functionality of the resulting CAR-T cells. In vivo efficacy was assessed in peripheral blood mononuclear cell and CD34⁺ stem cell humanized murine xenograft models of B cell leukemia.

Results: In vitro, NCtx displayed high specificity and transfection efficiency with both mcDNA and mRNA in primary T cells. Transposase mRNA facilitated genomic integration of the CAR gene, leading to the generation of stable CAR-T cells that exhibited antigen-specific cytotoxicity and cytokine release. In vivo, a single intravenous dose of NCtx induced robust CAR-T cell generation resulting in effective tumor control and significantly improved survival in two distinct xenograft models.

Conclusions: Our findings demonstrate for the first time that targeted LNPs can be employed for efficient DNA delivery to T cells in vitro and in vivo. We show that when combined with transposase technology, this LNP-based system can efficiently generate stable CAR-T cells directly in vivo, inducing potent and durable antitumor responses. NCtx represents a novel non-viral gene therapy vector for in vivo CAR-T therapy, offering a scalable and potentially more accessible alternative to traditional approaches in CAR-T cell generation.

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使用靶向脂质纳米颗粒的T细胞特异性非病毒DNA传递和体内CAR-T生成。

背景：体外嵌合抗原受体(CAR)-T疗法已经彻底改变了癌症治疗。然而，治疗的可及性受到成本高、制造时间长以及需要专门中心和住院治疗的阻碍。在体内产生CAR-T细胞的策略已经成为一种有前途的替代方案，可以绕过CAR-T制造瓶颈。目前大多数体内CAR-T方法虽然显示出令人鼓舞的临床前疗效，但依赖于瞬时信使RNA （mRNA）递送或病毒载体，这两种方法在效率、持久性和可扩展性方面都有局限性。为了解决这些挑战，我们开发了一种新的基于dna的靶向脂质纳米颗粒（LNP），我们将其命名为NCtx。方法：将编码CAR构建体和SB100x转座酶mRNA的微环DNA （mcDNA）包裹在一种新型脂质制剂中，这种脂质制剂被T细胞特异性抗cd7和抗cd3结合物功能化。在体外，我们评估了T细胞的特异性、mcDNA和mRNA的转染效率、转座子介导的CAR整合和产生的CAR-T细胞的功能。在外周血单核细胞和CD34+干细胞人源化小鼠B细胞白血病异种移植模型中评估体内疗效。结果：NCtx在体外对原代T细胞的mcDNA和mRNA均具有较高的特异性和转染效率。转座酶mRNA促进了CAR基因的基因组整合，从而产生稳定的CAR- t细胞，并表现出抗原特异性的细胞毒性和细胞因子释放。在体内，单次静脉注射NCtx诱导强大的CAR-T细胞生成，从而有效控制肿瘤，并显着提高两种不同异种移植模型的存活率。结论：我们的研究结果首次证明了靶向LNPs可以用于体外和体内T细胞的有效DNA递送。我们发现，当与转座酶技术结合时，这种基于lnp的系统可以在体内直接有效地产生稳定的CAR-T细胞，诱导有效和持久的抗肿瘤反应。NCtx代表了一种用于体内CAR-T治疗的新型非病毒基因治疗载体，为CAR-T细胞生成提供了一种可扩展且可能更容易获得的替代方法。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal for Immunotherapy of Cancer Biochemistry, Genetics and Molecular Biology-Molecular Medicine

CiteScore

17.70

自引率

4.60%

发文量

522

审稿时长

18 weeks

期刊介绍： The Journal for ImmunoTherapy of Cancer (JITC) is a peer-reviewed publication that promotes scientific exchange and deepens knowledge in the constantly evolving fields of tumor immunology and cancer immunotherapy. With an open access format, JITC encourages widespread access to its findings. The journal covers a wide range of topics, spanning from basic science to translational and clinical research. Key areas of interest include tumor-host interactions, the intricate tumor microenvironment, animal models, the identification of predictive and prognostic immune biomarkers, groundbreaking pharmaceutical and cellular therapies, innovative vaccines, combination immune-based treatments, and the study of immune-related toxicity.